Embedding and decoding three-dimensional watermarks into stereoscopic images

ABSTRACT

Disclosed inventions relates to methods and systems for encoding at least one watermark into a stereoscopic conjugate pair of images. An example method comprises the step of encoding the at least one watermark by shifting selected pixels of said pair of images in one or more directions. The one or more directions include a horizontal direction. In the disclosed embodiments, ancillary information is not required to support decoding of encoded watermarks in addition to the transmitted left and right images.

RELATED APPLICATIONS

This application is a continuation of U.S. application Ser. No.13/837,699, filed on Mar. 15, 2013, now U.S. Pat. No. ______, which is acontinuation of U.S. application Ser. No. 12/581,424, filed on Oct. 19,2009, now U.S. Pat. No. 8,401,223, which claims the benefit of U.S.Provisional No. 61/106,894, filed Oct. 20, 2008. Each of theabove-referenced applications, provisionals and patents is incorporatedby reference herein in its entirety.

BACKGROUND OF THE INVENTION

1. Field of the Invention

Embodiments described herein include methods and systems of embeddingand decoding three-dimensional watermarks in stereoscopic images.

2. Description of the Related Art

FIG. 1 a illustrates a conventional stereoscopic conjugate pair ofimages. Two images illustrated therein represent the right 101 and left103 images for a viewer. A viewer wearing a special set of glasses suchas the glasses with red-green filters would perceive a 3D image. Itshould be noted, however, that the red-green filters are included hereinonly as an example, and other known mechanisms can be employed such aslinearly and/or spherically polarized glasses as used within the Real 3DCinema or Disney Digital 3D systems. Known 3D technologies are describedin detail, such as, “3D Standards”, Matt Cowan, Chief ScientificOfficer, REAL 3D, Chairman, DC28-40 Stereoscopic Digital Cinema, and“REAL D 3D Theatrical System—A Technical Overview”, Matt Cowan, ChiefScientific Officer, REAL 3D, both of which are incorporated by referenceherein in their entirety.

Although only one set of images is represented, many 3D scenes can becollected together and made into a movie. Such a 3D movie that has beendigitized will be referred to as three dimensional (3D) video. Examplefeatured movies include “Journey to the Center of the Earth,” and futurefeature movies include Pixar offerings to include the Toy Story and Carsseries. More descriptions of three dimensional movies can be found in“RealD Deal Will Bring 3D To Small Theater Screens”, Sarah McBride, WallStreet Journal, Sep. 2, 2008., “Behind the Scenes of a Next Gen 3DFilm,” Cohan Andersen, PC Magazine, Jun. 18, 2008, and “Disney unveilsanimation slate,” Ben Fritz, Dade Hayes, Variety Magazine, Apr. 8, 2008,all of which are incorporated by reference herein in their entirety.

It should be noted that a 3D effect in 3D images is achieved by shiftingpixels in the horizontal direction, along the viewer's eye direction(i.e., x-parallax) to create the illusion of depth in the image scenes.That is, some parts of the 3D image appearing nearer to the viewer whilesome other parts of the images appearing farther from the viewer. Thefused effect creates a perceived 3D depth. This perceived depth ischaracterized by a depth map 107 shown in FIG. 1 b, in which lightercolored portions represent those that appear closer to the viewercompared with darker colored portions. More detailed description ofdepth map is provided in U.S. Pat. No. 6,215,898, which is incorporatedherein its entirety.

FIG. 2 illustrates example watermarks that can be encoded into 3Dimages. In conventional watermarking methods, watermarks, such as shownin FIG. 2, are encoded into lower bits of color information of 3Dimages. Although these conventional methods handle 3D objectwatermarking, these methods' primary focus on the primitive level (e.g.vertices, surfaces) where an object model (e.g. 3D wireframe model) isassumed prior to 3D transmission. The illustrated examples show awatermark 201 created by adjusting three dimensional mesh, and anotherwatermark 203 created by adjusting textures associated with threedimensional model. For such conventional methods, the encoded object'smodel is necessary in order to decode the watermark.

SUMMARY OF THE INVENTION

Embodiments of the disclosed invention relate to methods, systems, andapparatuses for encoding at least one watermark into a conventionalstereoscopic conjugate pair of images. For instance, the methodcomprises the step of encoding the at least one watermark by shiftingselected pixels of said pair of images in one or more directions. Theone or more directions include a horizontal direction.

In the disclosed embodiments, ancillary information is not required tosupport decoding of encoded watermarks in addition to the transmittedleft and right images. It should be noted that, herein, the termsembedding watermark(s) is used interchangeable with encodingwatermark(s).

In certain embodiments of the present invention, the step of encodingthe at least one watermark comprises generating a depth map in a digitalformat, encoding the at least one watermark into the depth map, therebygenerating a encoded depth map, and generating a modified stereoscopicconjugate pair of images based on said encoded depth map and theconventional stereoscopic conjugate pair of images. The step of encodingthe at least one watermark may comprise the step of encoding said atleast one watermark into one or more least significant bits of saiddepth map.

Some disclosed embodiments also include the step of encoding at leastone of said at least one watermark into each of quadrant of at least onestereo image pair. Various embodiments may also include encoding the atleast one watermark into a selected image pairs of a 3D movie.

In other example embodiments, a method for decoding at least onewatermark from a 3D pair of images that has been encoded with at leastone watermark. Embodiments may also include the steps of generating adepth map from the 3D pair of images, receiving information regarding anencoding algorithm that encoded said at least one watermark into said 3Dpair of images, and decoding said at least one watermark from said depthmap using a decoding algorithm based on said encoding algorithm.

Some example embodiments may also include the steps of modifying saiddepth map by removing said watermark information from the said depthmap, and generating a modified set of 3D pair of images based on themodified depth map. Embodiments can also include the steps of receivinga code from a remote location, matching the code to the at least onewatermark, and performing an action based on a result of the matchingstep.

In some embodiments, the action is preventing the 3D video from beingplayed when the result is a negative match, or the action is reportingto a second remote location when the result is a negative match. Theremote location is a database of pass-codes.

Various embodiments of present invention can also be implemented on aprocessor or processors (e.g., digital signal processors,microprocessors, or the like) coupled to a memory or memories.

BRIEF DESCRIPTION OF THE DRAWINGS

A more complete appreciation of embodiments of the invention, and manyof the attendant advantages thereof, will be readily apparent as thesame becomes better understood by reference to the following detaileddescription when considered in conjunction with the accompanyingdrawing, wherein:

FIG. 1 a is an illustration of a conventional stereoscopic pair ofimages;

FIG. 1 b is an illustration of conventional depth map derived from astereoscopic pair of images;

FIG. 2 is an illustration of conventional watermarks in 3D scenes;

FIG. 3 is a flow chart illustrating steps of encoding water marks inaccordance with various embodiments of the present invention;

FIG. 4 is an illustration of deriving a watermark from a depth map inaccordance with various embodiments of the present invention;

FIG. 5 is an illustration of the steps of embedding and then decodingprocesses using numerical examples in accordance with variousembodiments of the present invention;

FIG. 6 is an illustration of example stereoscopic images generated inaccordance with various embodiments of the present invention;

FIG. 7 is a flow chart illustrating an example verifying processingchain in accordance with various embodiments of the present invention;and

FIG. 8 is a flow chart illustrating another example verifying processingchain in accordance with various embodiments of the present invention.

It should be noted that a same reference numeral in different figuresindicate the same or similar featured functions or items depending onthe context.

DESCRIPTION OF VARIOUS EMBODIMENTS OF THE PRESENT INVENTION

To overcome some of the shortcomings described above, in the presentinvention, ancillary information, for example, is not required tosupport decoding of encoded watermarks in addition to the transmittedleft and right images. It should be noted that, herein, the termsembedding watermark(s) is used interchangeably with encodingwatermark(s).

FIG. 3 illustrates example steps of encoding watermarks to 3D images inaccordance with various embodiments of the present invention bytranslating selected pixels in the horizontal and/or verticaldirections. In other words, in addition to the pixels being shifted inthe original 3D video data to achieve the 3D effect, additional shiftingof selected pixels encodes the watermark onto the derived depth map.Because the human eyes are oriented along a horizontal axis, depth isperceived through different perspectives along a horizontal axis. At aminimum, 2 images must be transmitted—one for the left eye and one forthe right eye to create a three dimensional scene. Although notinclusive all methodologies to encode the watermark, the following stepsprovide an example process.

1. Within a video stream, select the target image pair (left 301, right303).

2. Within an image set, determine the true left and rightcorrespondences between images. These correspondences are generallyreported as x shifts between the two images, which is captured as aderived depth map 305.

3. The watermark payload is encoded within these shifts to encode awatermark 307. As an example, the encoded payload can be a serialnumber, a public key, or a record within a database.

4. Then create updated left and right images 309. In other words, shiftsare generated within the left 311 and right 312 images. These images arethen transmitted.

It is important to note that the shifts can be generated from the leftor right image and the shifts are generally taken in the horizontaldirection to be consistent the human eye's frame of reference. Thisapproach is invariant to various image compression techniques and isnon-destructive to the original colors in the video signal. Thefollowing computer program, written in Java and compiled using JavaDevelopment Kit Version 1.4, illustrates the encoding process in moredetail.

package vvi.encoders.mpeg2.watermark.*; /**  * Filename:DWMEmbedMethod.java  *  * This method reads an MPEG-2 file (as anexample), encodes a  * digital watermark, and transmits MPEG-2.  *  *For purposes of example, it is assumed that frame[i] is left eye  * andframe[i+1] is right eye where the display is handled by the  * stereoapplication device (e.g. TV, video machine, etc.).  *  * Kenneth A.Abeloe - Virginia Venture Industries, LLC  * **/ importjava.io.IOException; import java.util.Properties; importorg.apache.log4j.PropertyConfigurator; public class DWMEmbed { publicstatic org.apache.log4j.Logger mLog =org.apache.log4j.Logger.getLogger(DWMEmbedMethod.class); privateDigitalWaterMark dwm; // Constructor public DWMEmbed(String inputMark,int inFrameRate) { // Initialize the Digital Watermark for the EmbedFunctionality dwm = new DigitalWaterMark(inputMark, inFrameRate); //Iniitialize the event logger initializeLogger( ); } // Initialize thelogger private void initializeLogger( ) {  Properties logProperties =new Properties( );  try { logProperties.load(newFileInputStream(“log4j.properties”));PropertyConfigurator.configure(logProperties); mLog.info(“Logginginitialized.”);  }  catch(IOException e) { throw newRuntimeException(“Unable to load logging property file”,e);  } } //Method: Embed Watermark into Video Stream public booleanembedWatermark(String inputFileName, String outputFilename) { try { //Allocate input data streams VideoInputStream vin = newVideoInputStream(inputFileName); VideoOutputStream vout = newVideoOutputStream(outputFileName); // Log values mLog.info(“!!! Startingvideo stream encoding.”); // Get properties of video VideoProperties vp= new VideoProperties(inputFileName); int numLines = vp.getNumLines( );int numSamples = vp.getNumSamples( ); int numColors = vp.getNumColors(); // Allocate 2 images - 1 left and 1 right to hold collected videoimage byte[ ][ ] leftImage = new byte[numLines * numSamples][numColors];byte[ ][ ] rightImage = new byte[numLines * numSamples][numColors]; //Pull a left, right image out of the video stream, calculate depth map,// embed watermark, int index = 0; while (vin.play( ) == true) { // Grabframes at DWM frame rate specification if ((index % dwm.getFrameRate( ))== 0) { // Grab frame from image // returns numLines * numSamples *numColors leftImage = vin.getPixels(index); rightImage =vin.getPixels(index+1); // Determine depth map byte[ ] depthMap = newbyte[numLines * numSamples]; for (int i = 0; i < numLines; i++) { for (j= 0; j < numSamples; j++) { // Determine depth for current position; intpos = i * numSamples + j; depth [pos] = findDepth(leftImage[pos],rightImage[pos]); } } // Use depth map information to update left /right image // with watermark leftImage = dwm.updateImage(depth);rightImage = dwm.updateImage(depth); // Update the video with loadedleft and right images. vout.createFrame(leftImage, index);vout.createFrame(rightImage, index+1); } else { // Frame is not ofinterest based on frame rate sampling // Update output video with inputvideo only vout.createFrame(vin.getPixels(index);vout.createFrame(vin.getPixels(index+1); } } //end of while // Write outthe video file name vout.write( ); vout.flush( ); } // end of try //Catch any exceptions to the software catch(Exception e) {mLog.error(“Caught exception in DWMEmbed: ”,e.toString( )); returnfalse; } return true; } public static void main(String[ ] args) { //Digital Watermark Specifics int inFrameRate = (int)(newInteger(args[0]).toInt( )); // Example String Watermark StringinDigitalMark = new String(args[1]); // Input and Output FilenamesString inFile = new String(args[2]); String outFile = newString(args[3]); DWMEbed embedder = new DWMEbed(inFrameRate,inDigitalMark); boolean status = embedder(inFile, outFile); if (status){ mLog.info(“Completed video embedding for the following file: ” +inFile); mLog.info(“Completed output video is titled: ” + outFile); }else { mLog.error(“Errors processing the following input file: ” +inFile); } } }

FIG. 4 illustrates the steps of extracting the encoded watermark fromthe stereoscopic pair with an encoded watermark in accordance withvarious embodiments of the present invention. In particular, a decoder,which could be part of an apparatus such as a TV, a movie player (e.g.,DVDs, high definition DVD such as Blu-Ray Disc players), or astereoscopic video player, receives the 3D video signal. The signal isfirst separated into individual image pairs prior to viewing throughvarious methods such as the following:

1. Pixel interleaved—every other pixel belongs to the current view. Forexample pixel[i] belongs to left view and pixel[i+1] belongs to rightview.

2. Line interleaved—every other line belongs to the current view. Forexample pixel[i] through pixel[i+numSamples] belongs to the left viewwhile pixel[i+numSamples+1] belongs to the right view.

3. Scene interleaved—every other image belongs to the current view.

It should be noted that all image pairs could be encoded with watermarksor only selected image pairs can be encoded with watermarks. Inreference to FIG. 4, for the image pairs (e.g., left image 401 and rightimage 403) with encoded watermarks, the depth map 405 is derived. Fromthe derived depth map, the encoded watermark 407 is extracted. Thefollowing computer program, written in Java and compiled using the JavaDevelopment Kit Version 1.4, illustrates the encoding process in moredetail.

package vvi.encoders.mpeg2.watermark.*; /**  * Filename:DWMDecodeMethod.java  *  * This method reads an MPEG-2 file (as anexample), decodes the  * digital watermark and updates a log file withresults.  *  * For purposes of example, it is assumed that frame[i] isleft eye  * and frame[i+1] is right eye where the display is handled bythe  * stereo application device (e.g. TV, video machine, etc.).  *  *Kenneth A. Abeloe - Virginia Venture Industries, LLC  * **/ importjava.io.IOException; import java.util.Properties; importorg.apache.log4j.PropertyConfigurator; public class DWMDecode { publicstatic org.apache.log4j.Logger mLog =org.apache.log4j.Logger.getLogger(DWMEmbedMethod.class); privateDigitalWaterMark dwm; // Constructor public DWMDecode(int inFrameRate) {// Initialize the Digital Watermark for the Decode Functionality dwm =new DigitalWaterMark(null, inFrameRate); // Initialize the event loggerinitializeLogger( ); } // Initialize the logger private voidinitializeLogger( ) {  Properties logProperties = new Properties( ); try{ logProperties.load(new FileInputStream(“log4j.properties”));PropertyConfigurator.configure(logProperties); mLog.info(“Logginginitialized.”);  }  catch(IOException e) { throw newRuntimeException(“Unable to load logging property file”,e);  } } //Method: Decode Watermark from Video Stream public boolean decodeWatermark(String inputFileName) { try{ // Allocate input data streamsVideoInputStream vin = new VideoInputStream(inputFileName); // Logvalues mLog.info(“!!! Starting video stream decoding.”); // Getproperties of video VideoProperties vp = newVideoProperties(inputFileName); int numLines = vp.getNumLines( ); intnumSamples = vp.getNumSamples( ); int numColors = vp.getNumColors( ); //Allocate 2 images - 1 left and 1 right to hold collected video imagebyte[ ][ ] leftImage = new byte[numLines * numSamples][numColors]; byte[][ ] rightImage = new byte[numLines * numSamples][numColors]; // Pull aleft, right image out of the video stream, calculate depth map, // embedwatermark, int index = 0; while (vin.play( ) == true) { // Grab framesat DWM frame rate specification if ((index % dwm.getFrameRate( )) == 0){ // Grab frame from image // returns numLines * numSamples * numColorsleftImage = vin.getPixels(index); rightImage = vin.getPixels(index+1);// Determine depth map byte[ ] depthMap = new byte[numLines *numSamples]; for (int i = 0; i < numLines; i++) { for (j = 0; j <numSamples; j++) { // Determine depth for current position; int pos =i * numSamples + j; depth[pos] = findDepth(leftImage[pos],rightImage[pos]); } } // Use depth map information to determine digitalmark if (dwm.decodeMark(depth)) { mLog.info(“Watermark Determined to be:” + dwm.toString( )); } else { mLog.error(“Error determining watermarkfor index: ” + index); } } } // end of while } //end of try // Catch anyexceptions to the software catch(Exception e) { mLog.error(“Caughtexception in DWMEmbed: ”,e.toString( )); return false; } return true; }public static void main(String[ ] args) { // Digital Watermark Specificsint inFrameRate = (int)(new Integer(args[0]).toInt( )); DWMDecodedecoder = new DWMDecode(inFrameRate); boolean status = decoder(inFile);if (status) { mLog.info(“Completed video decoding for the followingfile: ” + inFile); } else { mLog.error(“Errors processing the followinginput file: ” + inFile); } } }

Various embodiments of the present invention can include both encodingand decoding function. The following explains an example process foradding watermark information into the depth map for a particular set ofimages (left, right) within a 3D video. In this example, the digitalwatermark to be encoded is a string to be encoded multiple times in the3D scene.

1. The string is encoded into a binary format. FIG. 5 illustrates anexample binary string to encode 501. As another example, a part of thestring “elephant” can be encoded in the binary representation of thefollowing:0110010101101100011001010111000001101000011000010110111001110100

2. The depth map from a pair of stereo images (not yet embedded with awatermark) is derived by correlating features along the horizontaldirection (or x direction) between left and right. For example purposesonly, for every pixel in the left image, search along the x-directionfor pixel correspondence (e.g. through correlation) in the right image.FIG. 5 show a part of an example depth map 503.

The following computer program, written in Java and compiled using JavaDevelopment Kit Version 1.4, illustrates the encoding process in moredetail.

short[ ] depthMap = new short[TotalLines][TotalSamples]; // Loop throughall lines and samples of the image for (int i = 0; i < TotalLines; i++){ for (int j = 0; j < TotalSamples; j++) { Initialize the localvariables. double matchResult; double maxResult = 0.0; // Chip the leftimage (reference image) tstLeftImage = chipImage(i, j, 20, 20,leftImage); // Search a window of values in the X direction for (k =j−20; k <= j+20; k++) { try{ // Chip various right images (test images)tstRightImage = chipImage(i, k, 20, 20, rightImage); // Correlate theimages together matchResult = correlateImages(tstLeftImage,tstRightImage); // Use maxResult to indntify the best match if(matchResult > maxResult) { maxResult = matchResult; resultIndex = k; }} // Catch any reading exceptions (e.g. borders) and keep going. catch(Exception e) { continue; } } // Delta difference between left and rightimage depthMap[i][j] = k − j; } }

3. As an example, the string is encoded by examining and regeneratingthe depth map using the binary encoded string. As shown by a string 505in FIG. 5, a binary string representing one line of a watermark can beencoded using an odd/even scheme within the depth map. Even numbers inthe depth map register to a binary value “0” and odd numbers in thedepth map register to a binary value “1”. As shown by a string 507 inFIG. 5, the depth map is adjusted to support the encoded string. Thisprocess is repeated multiple times to help defeat tampering attempts onthe processed video.

4. After the depth map has been adjusted to encode the value of thewatermark, the depth values are translated back to the original image inthe forms of depth shifts in the image as shown in FIG. 6, in which 601is a representative stereo image pair without a digital watermark, 603is a representative stereo image pair with a digital watermark. In thisexample, in 603, an example “elephant” string has been embedded.

In this example, the digital watermark to be extracted is a string to bedecoded from the 3D scene.

1. The depth map is derived by correlating features along the horizontaldirection (or x direction) between left and right. For example purposesonly, for every pixel in the left image, search along the x-directionfor pixel correspondence (e.g. through correlation) in the right image(as shown above).

2. The depth values are analyzed for their odd/even values and eithertranslated into a binary 0 for even numbers or a binary 1 for oddnumbers (see string 505 in FIG. 5). Because multiple digital watermarksmay have been introduced into the depth map, special characters (e.g.,00000000) may be introduced to break up the multiple watermarks.

3. Once the binary string is determined, the string is converted intoASCII and transmitted for verification processes.

FIGS. 7 and 8 illustrate the example uses of the decoded (or extracted)watermark information. In FIG. 7, in a retrieve watermark step 703, thewatermark information transmitted along with the 3D video signal (e.g.,the closed caption data 705) is retrieved. The retrieved watermarkinformation is compared with the watermark information decoded from thederived depth map 707 in a verify step 709. If the decoded watermarkinformation matches with the watermark information retrieved in step703, the 3D video is played on a video play system 711 stereoscopicallyusing, for example, red and green filters. If the decoded watermarkinformation does not match with the watermark information retrieved instep 703, the 3D video is not played. In FIG. 8, the decoded watermarkinformation is compared with the watermark information stored in anexternal source, such as a database, retrieved by a data server 801 in aretrieve watermark step 803. The retrieved watermark in these examplescan also be used to verify the video content, provide ancillaryinformation to the viewer (e.g., promotions, games, extras). The systemcould verify content by checking an encoded specific product identifier(e.g., serial number) versus the database specific product identifier.

While the invention has been described with reference to exemplaryembodiments, it will be understood by those skilled in the art thatvarious changes may be made and equivalents may be substituted forelements thereof without departing from the scope of the invention. Inaddition, many modifications may be made to adapt a particular situationto the teachings of the invention without departing from the essentialscope thereof. Therefore, it is intended that the invention not belimited to the particular embodiments for carrying out this invention,but that the invention will include all embodiments falling within thescope of the appended claims.

What is claimed is:
 1. A method for encoding at least one watermarkusing a stereoscopic conjugate (3D) pair of images by shifting one ormore pixels in at least a vertical direction, the method comprising:generating a depth map from the 3D pair of images; modifying said depthmap to encode the at least one watermark into said depth map; andgenerating a modified 3D pair of images based on the modified depth map,the depth map being modified such that at least one image of themodified pair of 3D images has one or more pixels shifted in at least avertical direction relative to the corresponding image in the 3D pair ofimages.
 2. The method of claim 1, wherein the depth map is modified suchthat at least one image of the modified pair of 3D images has one ormore pixels shifted in at least a horizontal direction relative to thecorresponding image in the 3D pair of images.
 3. The method of claim 1,further comprising: receiving information of an encoding algorithm formodifying said depth map to encode said at least one watermark into saiddepth map; and using the encoding algorithm to encode the at least onewatermark into said depth map.
 4. The method of claim 1, furthercomprising: determining a code associated with the at least onewatermark; and providing the code to an external device; matching thecode to the at least one watermark in the external device; andperforming an action based on whether the code matches the watermark. 5.The method of claim 4, wherein the action comprises preventing a threedimensional video from being played when the code does not match the atleast one watermark.
 6. A system of encoding at least one watermark intoa stereoscopic conjugate pair of images, the system comprising: agenerator configured to create a depth map from the stereoscopicconjugate pair of images; an encoder configured to encode said at leastone watermark into the depth map creating a modified depth map; aprocessor configured to create an updated stereoscopic conjugate pair ofimages from the modified depth map, the updated stereoscopic conjugatepair of images having one or more selected pixels shifted in at leastone direction when compared to the original stereoscopic conjugate pairof images, wherein the at least one direction includes a verticaldirection.
 7. The system of claim 6, wherein the at least one directionincludes a horizontal direction.
 8. The system of claim 6, wherein saidhaving one or more selected pixels shifted in at least one directionincludes having one or more least significant bits of said selectedpixels shifted in position to encode said at least one watermark.
 9. Thesystem of claim 8, wherein said shifted selected pixels includes pixelsselected in each of quadrant of one of the conjugate pair of images pairto thereby encode said at least one watermark.
 10. The method of claim6, wherein said stereoscopic conjugate pair of images pair is a part ofa three dimensional movie.
 11. A non-transitory computer readable mediumcomprising instructions that, when executed, cause an apparatus toperform a method for decoding at least one watermark from a stereoscopicconjugate pair of images, the method comprising: generating a depth mapfrom the 3D pair of images; decoding said at least one watermark fromsaid depth map; modifying said depth map by removing said watermarkinformation, said modifying said depth map comprising shiftinginformation from at least one pixel in a vertical direction, andgenerating a modified set of 3D images based on the modified depth map.12. The computer readable medium of claim 11, wherein said modifyingsaid depth map comprises shifting information from at least one pixel ina horizontal direction.
 13. The computer readable medium of claim 11,wherein the method further comprises: receiving information regarding anencoding algorithm that encoded said at least one watermark into said 3Dpair of images, and using a decoding algorithm based on said encodingalgorithm.
 14. The computer readable medium of claim 11, wherein themethod further comprises: receiving a code from an external source;matching the code to the at least one watermark; and performing anaction based on a result of said matching.
 15. A method of encoding atleast one watermark into a stereoscopic conjugate pair of imagescomprising encoding the at least one watermark by shifting selectedpixels of said at least one of said pair of images in at least avertical direction.
 16. The method of claim 15, wherein said encodingfurther comprises shifting selected pixels of said at least one of saidpair of images in at least a horizontal direction.
 17. The method ofclaim 15, further comprising generating a modified stereoscopicconjugate pair of images based on said shifting of said selected pixels.18. The method of claim 15, wherein said shifting of selected pixelscomprises shifting one or more least significant bits of said selectedpixels positions to encode said at least one watermark.
 19. The methodof claim 18, wherein said shifting of selected pixels comprisesselecting pixels in each of quadrant of at least one stereo image pairto shift to thereby encode said at least one watermark.
 20. The methodof claim 15, wherein said stereoscopic conjugate pair of images is apart of a three dimensional movie.